A film type IRAF filter and the manufacturing method thereof are disclosed. A method for manufacturing a film type IRAF filter includes steps of: providing a first carrier trimmed to a predetermined size in advance; forming a first substrate on the first carrier; forming an intermedia layer on a first surface of the first substrate; forming an Infrared-absorbing filter dye layer on the intermedia layer; forming a first multi-layers optical film on the Infrared-absorbing filter dye layer; forming a release layer on the first multi-layers optical film; removing the first carrier to expose a second surface opposite the first surface of the first substrate; forming a second multi-layers optical films on the second surface of the first substrate; and removing the release layer.

An embodiment of the present application provides a head-mounted display device. In the head-mounted display device, an optical imaging apparatus includes an image source element, a beam splitter element, and a reflective element configured to be aligned on an optical path; a structure of an absorbing element and a position of the absorbing element relative to the optical imaging apparatus configured to enable the absorbing element to absorb at least a portion of stray light in a first light region and cause real scene light in a second light region to pass through, the first light region is defined by a human eye mirror position and two ends of the beam splitter element, the second light region is defined by a human eye position, a human eye viewing angle, and an end of the beam splitter element that is away from the image source element, wherein the human eye mirror position is a mirror symmetry point of the human eye position with respect to the beam splitter element.

An embodiment of the present application provides a head-mounted display device. In the head-mounted display device, an optical imaging apparatus includes an image source element, a beam splitter element, and a reflective element configured to be aligned on an optical path; a structure of an absorbing element and a position of the absorbing element relative to the optical imaging apparatus configured to enable the absorbing element to absorb at least a portion of stray light in a first light region and cause real scene light in a second light region to pass through, the first light region is defined by a human eye mirror position and two ends of the beam splitter element, the second light region is defined by a human eye position, a human eye viewing angle, and an end of the beam splitter element that is away from the image source element, wherein the human eye mirror position is a mirror symmetry point of the human eye position with respect to the beam splitter element.

The present invention provides a metal oxide dispersion comprises a metal oxide, a millbase and a dispersant. The dispersant in the metal oxide is selected from a group consisting of a phosphoric acid polyester copolymer, a trimethoxysilane compound, a triethoxysilanes compound, dimethylamino ethyl methacrylate (DMAEMA) and a combination thereof, and the dispersion is substantially free of water. The metal oxide dispersion of the invention is useful for manufacturing an inkjet ink to provide a high-quality color image on a contact lens or a mold so as to produce a colored contact lens.

The present invention provides a metal oxide dispersion comprises a metal oxide, a millbase and a dispersant. The dispersant in the metal oxide is selected from a group consisting of a phosphoric acid polyester copolymer, a trimethoxysilane compound, a triethoxysilanes compound, dimethylamino ethyl methacrylate (DMAEMA) and a combination thereof, and the dispersion is substantially free of water. The metal oxide dispersion of the invention is useful for manufacturing an inkjet ink to provide a high-quality color image on a contact lens or a mold so as to produce a colored contact lens.

To appropriately suppress reflection of far-infrared rays, and appropriately form an antireflection film. A far-infrared ray transmission member (20) includes a base material (30) that transmits far-infrared rays, and a functional film (32) that is formed on the base material (30) and includes a low refractive index layer (34) containing oxide as a principal component and having a refractive index equal to or smaller than 1.5 with respect to light at a wavelength of 10 μm. The low refractive index layer (34) contains MgO as a principal component, and a content of MgO is equal to or larger than 50 mass % and equal to or smaller than 100 mass % with respect to the entire low refractive index layer (34).

To appropriately suppress reflection of far-infrared rays, and appropriately form an antireflection film. A far-infrared ray transmission member (20) includes a base material (30) that transmits far-infrared rays, and a functional film (32) that is formed on the base material (30) and includes a low refractive index layer (34) containing oxide as a principal component and having a refractive index equal to or smaller than 1.5 with respect to light at a wavelength of 10 μm. The low refractive index layer (34) contains MgO as a principal component, and a content of MgO is equal to or larger than 50 mass % and equal to or smaller than 100 mass % with respect to the entire low refractive index layer (34).

According to at least one exemplary embodiment a heliostat driven reactor may be provided. The heliostat driven reactor may include one or more photonic collectors that collect photonic energy and disperses photonic energy, one or more mirrors which concentrate the photonic energy dispersed by the one or more photonic collectors, one or more gain mediums which receive, on one or more absorption faces, the photonic energy dispersed by the photonic energy collector and the photonic energy concentrated by the one or more mirrors, and/or a photoelectric material which receives photonic energy from the one or more gain mediums and converts the photonic energy into electrical energy.

Optically clear adhesive or coating layers can be prepared by preparing a curable mixture, coating the curable mixture to form a layer, partially curing the curable mixture, drying the coated layer, and fully curing the curable mixture. The curable mixture may also be partially cured and then coated, dried and fully cured. The curable mixture includes two free radically polymerizable monomer compositions that are relatively incompatible and a transient compatibilizer, such as a solvent. Polymers of the two monomer compositions, if polymerized separately and blended, form phase separated domains. The curable mixture provides for adhesive or coating layers that are optically clear.

Optically clear adhesive or coating layers can be prepared by preparing a curable mixture, coating the curable mixture to form a layer, partially curing the curable mixture, drying the coated layer, and fully curing the curable mixture. The curable mixture may also be partially cured and then coated, dried and fully cured. The curable mixture includes two free radically polymerizable monomer compositions that are relatively incompatible and a transient compatibilizer, such as a solvent. Polymers of the two monomer compositions, if polymerized separately and blended, form phase separated domains. The curable mixture provides for adhesive or coating layers that are optically clear.